Light source unit and projection-type display

ABSTRACT

A light source unit according to an embodiment of the disclosure includes a substrate configured to be rotatable, a phosphor layer disposed at a center of the substrate, a light source that irradiates the phosphor layer with exciting light, and a support section that supports a portion, of the substrate, except for the center of the substrate. This makes it difficult for heat generated in the phosphor layer to travel to a motor through the substrate.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a U.S. National Phase of International PatentApplication No. PCT/JP2016/062496 filed on Apr. 20, 2016, which claimspriority benefit of Japanese Patent Application No. JP 2015-099920 filedin the Japan Patent Office on May 15, 2015. Each of the above-referencedapplications is hereby incorporated herein by reference in its entirety.

TECHNICAL FIELD

The disclosure relates to a light source unit and a projection-typedisplay.

BACKGROUND ART

As a light source used for a projection-type display such as aprojector, a solid-state light source having a long life and a widecolor gamut has been attracting attention. In recent years, a lightsource unit that utilizes light emitted from a phosphor by irradiatingthe phosphor with light of a solid-state light source has been used fora projector, etc.

The above-described light source unit includes, for example, a phosphorlayer, and a solid-state light source that irradiates the phosphor layerwith exciting light. For light emission of the phosphor layer, there isa phenomenon called luminance saturation or temperature quenching. Thisis such a phenomenon that, in a case where an output of the excitinglight is increased, a part of a conversion loss in the phosphor layerchanges to heat that causes the phosphor layer to generate heat, andfluorescence conversion efficiency thereby drops. In a state where thefluorescence conversion efficiency is low, an efficient, bright lightsource unit is not implementable. Hence, the phosphor layer is providedon a surface of a substrate having high thermal conductivity.

CITATION LIST Patent Literature

PTL 1: Japanese Unexamined Patent Application Publication No.2013-130605

SUMMARY OF INVENTION

Incidentally, a phosphor layer is rotated by a motor attached to asubstrate having high thermal conductivity. There has been such an issuethat, in a case where heat generated in the phosphor layer transfers tothe motor through the substrate, a temperature rise of the motor occurs,which causes a decline in reliability of the motor.

It is therefore desirable to provide a light source unit and aprojection-type display that make it possible to suppress a decline inreliability of a motor due to a temperature rise of the motor.

A light source unit according to an embodiment of the disclosureincludes a substrate configured to be rotatable, a phosphor layerdisposed at a center of the substrate, a light source that irradiatesthe phosphor layer with exciting light, and a support section thatsupports a portion, of the substrate, except for the center of thesubstrate.

A projection-type display according to an embodiment of the disclosureincludes a substrate configured to be rotatable, a phosphor layerdisposed at a center of the substrate, a light source that irradiatesthe phosphor layer with exciting light, and a support section thatsupports a portion, of the substrate, except for the center of thesubstrate. This projection-type display further includes an opticalmodulation section that generates image light by modulating the excitinglight outputted from the light source, on a basis of an image signal,and a projection section that projects the image light generated by theoptical modulation section.

In the light source unit and the projection-type display according tothe respective embodiments of the disclosure, there is provided thesupport section that supports the portion, of the substrate, except forthe center of the substrate. This makes it difficult for heat generatedin the phosphor layer to travel to a motor through the substrate, ascompared with a case where a support section supports an entire centerof a substrate, at which a phosphor layer is disposed.

The light source unit and the projection-type display according to therespective embodiments of the disclosure make it difficult for the heatgenerated in the phosphor layer to travel to the motor through thesubstrate and thus, it is possible to suppress a decline in reliabilityof the motor due to a temperature rise of the motor. It is to be notedthat effects of the disclosure are not limited to those described above,and may be any of effects described herein.

BRIEF DESCRIPTION OF DRAWINGS

FIGS. 1(A) and 1(B) are diagrams illustrating a cross-sectionalconfiguration example and a plane configuration example of a phosphorsubstrate used for a light source unit according to a first embodimentof the disclosure.

FIG. 2 is a diagram illustrating a modification example of across-sectional configuration of the phosphor substrate illustrated inFIGS. 1(A) and 1(B).

FIGS. 3(A) and 3(B) are diagrams illustrating a modification example ofa cross-sectional configuration and a modification example of a planeconfiguration of the phosphor substrate illustrated in FIGS. 1(A) and1(B).

FIG. 4 is a diagram illustrating a cross-sectional configuration examplewhen a shaft of a motor is attached to the phosphor substrateillustrated in FIGS. 1(A) and 1(B), through an attachment.

FIG. 5 is a perspective diagram illustrating an exploded state ofcomponents attached to the phosphor substrate in FIG. 4.

FIG. 6 is a diagram illustrating a cross-sectional configuration examplewhen a shaft of a motor is attached to the phosphor substrateillustrated in FIGS. 1(A) and 1(B), through an attachment.

FIG. 7 is a perspective diagram illustrating an exploded state ofcomponents attached to the phosphor substrate in FIG. 6.

FIG. 8 is a diagram illustrating a cross-sectional configuration examplewhen a shaft of a motor is attached to the phosphor substrateillustrated in FIGS. 1(A) and 1(B), through an attachment.

FIG. 9 is a perspective diagram illustrating an exploded state ofcomponents attached to the phosphor substrate in FIG. 8.

FIG. 10 is a diagram illustrating a cross-sectional configurationexample when a shaft of a motor is attached to the phosphor substrateillustrated in FIGS. 1(A) and 1(B), through an attachment.

FIG. 11 is a perspective diagram illustrating an exploded state ofcomponents attached to the phosphor substrate in FIG. 10.

FIG. 12 is a diagram illustrating a cross-sectional configurationexample when a shaft of a motor is attached to the phosphor substrateillustrated in FIGS. 1(A) and 1(B), through an attachment.

FIG. 13 is a perspective diagram illustrating an exploded state ofcomponents attached to the phosphor substrate in FIG. 12.

FIG. 14 is a diagram illustrating a schematic configuration example ofthe light source unit according to the first embodiment of thedisclosure.

FIG. 15 is a diagram for description of an example of application ofexciting light to the phosphor substrate, in the light source unitillustrated in FIG. 14.

FIG. 16 is a diagram for description of an example of application ofexciting light to the phosphor substrate, in the light source unitillustrated in FIG. 14.

FIG. 17 is a diagram for description of an example of application ofexciting light to the phosphor substrate, in the light source unitillustrated in FIG. 14.

FIG. 18 is a diagram for description of an example of application ofexciting light to the phosphor substrate, in the light source unitillustrated in FIG. 14.

FIG. 19 is a diagram illustrating a schematic configuration example of aprojection-type display according to a second embodiment of thedisclosure.

DESCRIPTION OF EMBODIMENTS

Some embodiments of the disclosure will be described below in detailwith reference to the drawings. The following description is a specificexample of the invention, and the invention is not limited to thefollowing embodiments. In addition, as for placement and dimensions, aswell as a dimension ratio, etc., of each component illustrated in eachfigure, the invention is not limited thereto either. It is to be notedthat the description will be provided in the following order.

1. First Embodiment (a phosphor substrate, and a light source unit)

2. Second Embodiment (a projection-type display)

1. <First Embodiment>

[Configuration]

A configuration of a phosphor substrate 1 used for a light source unitaccording to a first embodiment of the disclosure will be described. Thephosphor substrate 1 corresponds to a specific example of a “phosphorsubstrate” of the disclosure. FIGS. 1(A) and 1(B) illustrate across-sectional configuration example and a plane configuration exampleof the phosphor substrate 1 according to the first embodiment of thetechnology. The phosphor substrate 1 is applicable to, for example, alight conversion section 2A of a light source unit 2 (see FIG. 14)described later. The phosphor substrate 1 includes a substrate 20 and aphosphor layer 10.

The substrate 20 is configured to be rotatable, and is, for example,rotationally symmetric. The substrate 20 has, for example, a shape to berotationally symmetric about a rotation axis AX1 of a shaft 41 describedlater, when being attached to the shaft 41 through an attachment 42described later. The substrate 20 has, for example, a disk shape asillustrated in FIG. 1 (B). The substrate 20 is configured of a materialhaving high thermal conductivity, and is configured of, e.g., ametal/alloy-based material, a ceramic-based material, a ceramic-metalsystem, a crystal such as sapphire, diamond, glass, etc. Here, examplesof the metal/alloy-based material include Al, Cu, Mo, W, CuW, etc.Examples of the ceramic-based material include SiC, AlN, Al₂O₃, Si₃N₄,ZrO₂, Y₂O₃, etc. Examples of the ceramic-metal system include SiC—Al,SiC—Mg, SiC—Si, etc.

The substrate 20 has a diameter D2 of, for example, 20 mm or more and100 mm or less. The substrate 20 has a thickness of, for example, 0.3 mmor more and 2.0 mm or less. The substrate 20 may be configured of asingle layer, or may be configured of a plurality of layers. When thesubstrate 20 is configured of a single layer, it is preferable that thesubstrate 20 be configured of a material having high reflectance. Whenthe substrate 20 is configured of a plurality of layers, it ispreferable that a layer forming a top surface of the substrate 20 beconfigured of a material having high reflectance.

The phosphor layer 10 is disposed at a center of the substrate 20. Thephosphor layer 10 has, for example, a disk shape as illustrated in FIG.1 (B), and is disposed concentrically with the substrate 10. When lightof a specific wavelength enters, the phosphor layer 10 is excited by thelight (incident light) of the specific wavelength to emit light of awavelength region different from the wavelength of the incident light.The phosphor layer 10 includes, for example, a fluorescent substancethat emits yellow fluorescence (yellow light) when excited by blue lighthaving a center wavelength of about 445 nm. The phosphor layer 10 isconfigured, for example, to convert a part of blue light into yellowlight when the blue light enters. Examples of the fluorescent substanceincluded in the phosphor layer 10 include a YAG-based phosphor (e.g.,Y₃Al₅O₁₂). The YAG-based phosphor is one of fluorescent substances thatemit yellow fluorescence (yellow light) when excited by blue lighthaving a center wavelength of about 445 nm. In a case where thefluorescent substance included in the phosphor layer 10 is the YAG-basedphosphor, the YAG-based phosphor may be doped with Ce.

The phosphor layer 10 may include an oxide phosphor other than theYAG-based phosphor. The phosphor layer 10 may include a phosphor otherthan the oxide phosphor, or may include, for example, an oxynitridephosphor, a nitride-based phosphor, a sulfide phosphor, or asilicate-based phosphor. Here, the oxynitride phosphor is, for example,a BSON phosphor (e.g., Ba₃Si₆O₁₂N₂: Eu²⁺). The nitride-based phosphoris, for example, a CASN phosphor (e.g., CaAlSiN₃: Eu) or a SiAlONphosphor. The sulfide phosphor is, for example, a SGS phosphor (e.g.,SrGa₂S₄: Eu). The silicate-based phosphor is, for example, a TEOSphosphor (e.g., Si(OC₂H₅)₄).

The phosphor layer 10 includes, for example, a powder phosphor, and abinder that holds the powder phosphor. The phosphor layer 10 may be, forexample, a powder phosphor, and formed by solidifying the powderphosphor by using an inorganic material. The phosphor layer 10 may beformed by, for example, applying a material, which includes a powderphosphor and a binder that holds the powder phosphor, onto the substrate20. The phosphor layer 10 may be formed by, for example, sintering amaterial, which includes a powder phosphor and a binder (e.g., a ceramicmaterial) that holds the powder phosphor. It is to be noted thatexamples of the powder phosphor included in the phosphor layer 10include the above-described various phosphors. The phosphor layer 10 maybe a polycrystalline plate configured of a phosphor material. Thepolycrystalline plate is formed by processing a polycrystalline materialconfigured of a phosphor material into a plate shape.

It is preferable that the substrate 20 and the phosphor layer 10 beconfigured of materials so that a difference in linear expansioncoefficient between the substrate 20 and the phosphor layer 10 is 1×10⁻⁶cm/° C. or less per 1 m. In a case where the phosphor layer 10 is apolycrystalline plate configured of the YAG-based phosphor doped withCe, the linear expansion coefficient of the phosphor layer 10 is about8.0×10⁻⁶ m/° C. per 1 m. In a case where the substrate 20 is configuredof a titanium alloy, the linear expansion coefficient of the substrate20 is about 8.4×10⁻⁶ m/° C. per 1 m. Hence, in a case where the phosphorlayer 10 is the polycrystalline plate configured of the YAG-basedphosphor doped with Ce and the substrate 20 is configured of thetitanium alloy, the difference in linear expansion coefficient betweenthe substrate 20 and the phosphor layer 10 is 0.4×10⁻⁶ cm/° C. per 1 m.In other words, in a case where the phosphor layer 10 is apolycrystalline plate configured of a ceramic material and the substrate20 is configured of a titanium alloy, the difference in linear expansioncoefficient between the substrate 20 and the phosphor layer 10 is 1×10⁻⁶cm/° C. or less per 1 m.

The substrate 20 may be configured of a material having a large linearexpansion coefficient, e.g., aluminum (23×10⁻⁶ cm/° C. per 1 m),stainless steel (17×10⁻⁶ cm/° C. per 1 m), or copper (17×10⁻⁶ cm/° C.per 1 m). In this case, however, the difference in linear expansioncoefficient between the substrate 20 and the phosphor layer 10 is avalue much larger than 1×10⁻⁶ cm/° C. per 1 m.

Assume that, for example, the phosphor layer 10 is configured of aceramic material and the substrate 20 is configured of aluminum.Further, assume that, for example, the phosphor layer 10 has a diameterof 20 mm, and the phosphor layer 10 has a temperature of 200° C. and thesubstrate 20 has a temperature of 150° C., at a room temperature of 20°C. Respective expansion quantities at this time are as follows.

Phosphor layer 10: 14.4 mm

Substrate 20: 29.9 mm

The difference in expansion quantity is about 15.5 mm.

On the other hand, assume that, for example, the phosphor layer 10 isconfigured of a ceramic material, and the substrate 20 is configured ofa titanium alloy. Further, assume that, for example, the phosphor layer10 has a diameter of 20 mm, and the phosphor layer 10 has a temperatureof 200° C. and the substrate 20 has a temperature of 150° C., at a roomtemperature of 20° C. Respective expansion quantities at this time areas follows.

Phosphor layer 10: 14.4 mm

Substrate 20: 10.9 mm

The difference in expansion quantity is about 3.5 mm, which is as smallas ⅕ of the above-described expansion quantity.

The phosphor layer 10 has a diameter D1 of, for example, 3 mm or moreand 60 mm or less. When the substrate 20 has the diameter D2 of 20 mm,the diameter D1 of the phosphor layer 10 is, for example, 3 mm. When thediameter D2 of the substrate 20 is 100 mm, the diameter D1 of thephosphor layer 10 is, for example, 60 mm. The phosphor layer 10 may beconfigured of a single layer, or may be configured of a plurality oflayers. When the phosphor layer 10 is configured of a plurality oflayers, a layer forming a surface (an undersurface) on substrate 20 sideof the phosphor layer 10 may include a material having high reflectance.

The phosphor substrate 1 may further include, for example, asillustrated in FIGS. 1(A) and 1(B), a fixing layer 30 between thesubstrate 20 and the phosphor layer 10 to fix the substrate 20 and thephosphor layer 10 to each other. The fixing layer 30 includes, forexample, an organic adhesive, or an inorganic adhesive, low-meltingglass, or solder. The organic adhesive used as the fixing layer 30 is,for example, acrylic resin, epoxy resin, silicone resin, or fluororesin.The inorganic adhesive used as the fixing layer 30 is, for example, asilica adhesive, an alumina adhesive, or a ceramic-based adhesive. Thelow-melting glass is, for example, fritted glass or silicate glass.

It is to be noted, for example, as illustrated in FIG. 2, the fixinglayer 30 may be omitted in the phosphor substrate 1. In this case, thephosphor layer 10 is directly fixed to the substrate 20 withoutintervention of the fixing layer 30. In this case, a binder included inthe substrate 20 and the phosphor layer 10 may include a ceramicmaterial. At this time, the substrate 20 and the phosphor layer 10 maybe formed, for example, by performing sintering in a state where aplurality of layers including the ceramic material are bonded to eachother.

In the phosphor substrate 1, in a case where the fixing layer 30 isomitted, the substrate 20 and the phosphor layer 10 may be bonded toeach other by, for example, ambient temperature bonding or opticalcontact. For the ambient temperature bonding, there aresurface-activated bonding and atomic diffusion bonding. Thesurface-activated bonding refers to a bonding method of bonding twomaterials without adding an adhesive, heat, pressure, etc., byperforming a surface treatment thereby causing activation on bondingsurfaces of the materials in a vacuum. The bonding surfaces of thematerials are activated, by removing oxide and impurities present on thebonding surfaces of the materials by argon spattering, etc. The atomicdiffusion bonding refers to a bonding method of bonding two materials atan ambient temperature, without application of pressure, and withoutapplication of voltage, by forming fine crystal films in an ultrahighvacuum on bonding surfaces of materials, and overlaying two thin filmsin a vacuum. The optical contact refers to a bonding method ofstabilizing molecules of planes to make these molecules behave likeinternal molecules, by causing interaction between the molecules of theplanes, by bringing the planes subjected to precision polishing intotight contact with each other.

It is to be noted that, for example, as illustrated in FIGS. 3(A) and3(B), the phosphor layer 10 may be shaped like a ring having an opening10H at a center of the phosphor layer 10. At this time, the phosphorlayer 10 is disposed, for example, concentrically with the substrate 20.In addition, at this time, the phosphor layer 10 has a diameter (anouter diameter) equal to the diameter D1 described above. The phosphorlayer 10 has an inner diameter (a diameter of the opening 10H) smallerthan an inner diameter of a radiation region (an optical irradiationregion 10B (see FIG. 14) described later) of exciting light to irradiatethe phosphor layer 10.

FIG. 4 illustrates a cross-sectional configuration example of thephosphor substrate 1, the attachment 42, the shaft 41, and screws 43,when the shaft 41 of a motor is attached to the phosphor substrate 1through the attachment 42. FIG. 5 perspectively illustrates an explodedstate of components attached to the phosphor substrate 1 in FIG. 4. Itis to be noted that FIG. 4 illustrates an example of a state where theshaft 41 of the motor is attached to the phosphor substrate 1illustrated in FIGS. 1(A) and 1(B), through the attachment 42. It is tobe noted that the shaft 41 of the motor may be attached to, instead ofthe phosphor substrate 1 illustrated in FIGS. 1(A) and 1(B), thephosphor substrate 1 illustrated in FIGS. 3(A) and 3(B), through theattachment 42.

The attachment 42 is intended to couple the phosphor substrate 1 and afront end of the shaft 41 of the motor to each other. The attachment 42corresponds to a specific example of a “support section” of thedisclosure. The attachment 42 is configured to be rotatable, and is, forexample, rotationally symmetric. The attachment 42 has, for example, adisk shape. The attachment 42 supports a portion except for the centerof the substrate 20. The attachment 42 supports a portion, of thesubstrate 20, not facing the phosphor layer 10. The attachment 42supports, for example, as illustrated in FIG. 4, only the portion, ofthe substrate 20, not facing the phosphor layer 10. In other words, theattachment 42 is fixed to the substrate 20 while avoiding, for example,a portion, of the substrate 20, immediately below the phosphor layer 10.

The shaft 41 is fixed to an undersurface of the attachment 42, and, forexample, fixed to the undersurface of the attachment 42 by an adhesive,etc. The attachment 42 has, for example, a shape to be rotationallysymmetric about the rotation axis AX1 of the shaft 41, when theattachment 42 is attached to the shaft 41. The attachment 42 has, forexample, a concave section 42A having a recess formed at least at aportion facing the phosphor layer 10. The concave section 42Acorresponds to a specific example of a “first concave section” and a“concave section” of the technology. The concave section 42A forms aclearance between a portion, of the substrate 20, facing the phosphorlayer 10 and the attachment 42.

The attachment 42 has, for example, a plurality of openings 42B forengagement with the screws 43, at an outer edge of the attachment 42.The substrate 20 has an opening 21 for engagement with the screw 43, ina one-by-one fashion, at a location corresponding to each of theopenings 42B when the attachment 42 is attached to the substrate 20. Theattachment 42 is fixed to the substrate 20, by engaging the screws 43 inthe openings 42B and the openings 21. It is to be noted that theopenings 42B, the openings 21, and the screws 43 may be omitted. In thatcase, however, the attachment 42 is fixed to the substrate 20 through,for example, an adhesive, etc.

FIG. 6 illustrates a cross-sectional configuration example of thephosphor substrate 1, the attachment 42, the shaft 41, and the screws43, when the shaft 41 of the motor is attached to the phosphor substrate1 through the attachment 42. FIG. 7 perspectively illustrates anexploded state of components attached to the phosphor substrate 1 inFIG. 6. It is to be noted that FIG. 6 illustrates an example of a statewhere the shaft 41 of the motor is attached to the phosphor substrate 1illustrated in FIGS. 1(A) and 1(B), through the attachment 42. It is tobe noted that the shaft 41 of the motor may be attached to, instead ofthe phosphor substrate 1 illustrated in FIGS. 1(A) and 1(B), thephosphor substrate 1 illustrated in FIGS. 3(A) and 1(B), through theattachment 42.

The attachment 42 has, for example, as illustrated in FIG. 6 and FIG. 7,an opening 42C for engagement with the front end of the shaft 41. Theopening 42C corresponds to a specific example of a “fixing section” ofthe disclosure. The opening 42C is provided at an undersurface of theconcave section 42A to fix the shaft 41 of the motor. The shaft 41 isfixed to the attachment 42, by engaging the front end of the shaft 41 inthe opening 42C. At this time, it is preferable that, for example, asillustrated in FIG. 6 and FIG. 7, the shaft 41 have a convex section 41Amatching with shape and size of the opening 42C, at the front end of theshaft 41.

FIG. 8 illustrates a cross-sectional configuration example of thephosphor substrate 1, an attachment 44, the shaft 41, and the screws 43,when the shaft 41 of the motor is attached to the phosphor substrate 1through the attachment 44. FIG. 9 perspectively illustrates an explodedstate of components attached to the phosphor substrate 1 in FIG. 8. Itis to be noted that FIG. 8 illustrates an example of a state where theshaft 41 of the motor is attached to the phosphor substrate 1illustrated in FIGS. 1(A) and 1(B), through the attachment 44. It is tobe noted that the shaft 41 of the motor may be attached to, instead ofthe phosphor substrate 1 illustrated in FIGS. 1(A) and 1(B), thephosphor substrate 1 illustrated in FIGS. 3(A) and 3(B), through theattachment 42.

The attachment 44 is intended to couple the phosphor substrate 1 and thefront end of the shaft 41 of the motor to each other. The attachment 44corresponds to a specific example of a “support section” of thedisclosure. The attachment 44 is configured to be rotatable, and is, forexample, rotationally symmetric. The attachment 44 has, for example, adisk shape. The attachment 44 supports a portion except for the centerof the substrate 20. The attachment 44 supports a portion, of thesubstrate 20, not facing the phosphor layer 10. The attachment 44supports, for example, as illustrated in FIG. 8, only the portion, ofthe substrate 20, facing the phosphor layer 10. In other words, theattachment 44 is fixed to the substrate 20, while avoiding, for example,a portion, of the substrate 20, immediately below the phosphor layer 10.

The shaft 41 is fixed to an undersurface of the attachment 44. Forexample, the shaft 41 may be fixed to the undersurface of the attachment44 by an opening 44C, etc. described later, or may be fixed to theundersurface of the attachment 44 by an adhesive, etc. The attachment 44has, for example, a shape to be rotationally symmetric about therotation axis AX1 of the shaft 41, when the attachment 44 is attached tothe shaft 41.

The attachment 44 has, for example, a plurality of concave sections 44Bfor engagement with the screws 43, at an outer edge of a top surface ofthe attachment 44. The attachment 44 further has, for example, aplurality of convex sections 44A, at the outer edge (i.e., a portion notfacing the phosphor layer 10) of the top surface of the attachment 44.The convex section 44A corresponds to a specific example of a “convexsection” of the disclosure. The plurality of convex sections 44A form aclearance between the portion, of the substrate 20, facing the phosphorlayer 10 and the attachment 42. Each of the convex sections 44A has oneor more of the concave sections 44B, at a top surface. The substrate 20has the opening 21 for engagement with the screw 43, at a locationcorresponding to each of the concave sections 44B when the attachment 44is attached to the substrate 20. The attachment 44 is fixed to thesubstrate 20, by engaging the screws 43 in the concave sections 44B andthe openings 21. It is to be noted that the concave sections 44B, theopenings 21, and the screws 43 may be omitted. In that case, however,each of the convex sections 44A of the attachment 44 is fixed to thesubstrate 20 through, for example, an adhesive, etc.

FIG. 10 illustrates a cross-sectional configuration example of thephosphor substrate 1, the attachment 42, the shaft 41, and the screws43, when the shaft 41 of the motor is attached to the phosphor substrate1 through the attachment 42. FIG. 11 perspectively illustrates anexploded state of components attached to the phosphor substrate 1 inFIG. 10. It is to be noted that FIG. 10 illustrates an example of astate where the shaft 41 of the motor is attached to the phosphorsubstrate 1 illustrated in FIGS. 1(A) and 1(B), through the attachment42. It is to be noted that the shaft 41 of the motor may be attached to,instead of the phosphor substrate 1 illustrated in FIGS. 1(A) and 1(B),the phosphor substrate 1 illustrated in FIGS. 3(A) and 3(B), through theattachment 42.

The attachment 42 has, for example, as illustrated in FIG. 10 and FIG.11, a ring-shaped concave section 42D, around a location (e.g., theopening 42C) to which the shaft 41 is fixed, of the undersurface of theconcave section 42A. The concave section 42D corresponds to a specificexample of a “third concave section” of the disclosure. Hence, adistance between the phosphor layer 10 (a heat source) and the shaft 41is increased, for example, as indicated with an arrow in FIG. 10.

FIG. 12 illustrates a cross-sectional configuration example of thephosphor substrate 1, an attachment 45, the shaft 41, and the screws 43,when the shaft 41 of the motor is attached to the phosphor substrate 1through the attachment 45. FIG. 13 perspectively illustrates an explodedstate of components attached to the phosphor substrate 1 in FIG. 12. Itis to be noted that FIG. 12 illustrates an example of a state where theshaft 41 of the motor is attached to the phosphor substrate 1illustrated in FIGS. 1(A) and 1(B), through the attachment 45. It is tobe noted that the shaft 41 of the motor may be attached to, instead ofthe phosphor substrate 1 illustrated in FIGS. 1(A) and 1(B), thephosphor substrate 1 illustrated in FIGS. 3(A) and 3(B), through theattachment 45.

The attachment 45 is intended to couple the phosphor substrate 1 and thefront end of the shaft 41 of the motor to each other. The attachment 45corresponds to a specific example of a “support section” of thedisclosure. The attachment 45 is configured to be rotatable, and is, forexample, rotationally symmetric. The attachment 45 has, for example, adisk shape. The attachment 45 supports a portion except for the centerof the substrate 20. The attachment 45 supports a portion, of thesubstrate 20, not facing the phosphor layer 10. The attachment 45supports, for example, as illustrated in FIG. 12, the portion, of thesubstrate 20, not facing the phosphor layer 10 and a part of a portion,of the substrate 20, facing the phosphor layer 10.

The shaft 41 is fixed to an undersurface of the attachment 45. Forexample, the shaft 41 may be fixed to the undersurface of the attachment45 by the above-described opening 42C, etc., or may be fixed to theundersurface of the attachment 45 by an adhesive, etc. The attachment 45has, for example, a shape to be rotationally symmetric about therotation axis AX1 of the shaft 41, when the attachment 45 is attached tothe shaft 41. The attachment 45 has, for example, a plurality of concavesections 45A, at a portion facing the phosphor layer 10. The concavesection 45A corresponds to a specific example of a “second concavesection” of the technology. The concave sections 45A each form aclearance between the substrate 20 and the attachment 45.

The attachment 45 has, for example, a plurality of openings 45B forengagement with the screws 43, at an outer edge of the attachment 45.The substrate 20 has the opening 21 for engagement with the screw 43, ina one-by-one fashion, at a location corresponding to each of theopenings 45B when the attachment 45 is attached to the substrate 20. Theattachment 45 is fixed to the substrate 20 by engaging the screws 43 inthe openings 45B and the openings 21. It is to be noted that theopenings 45B, the openings 21, and the screws 43 may be omitted. In thatcase, however, the attachment 45 is fixed to the substrate 20 through,for example, an adhesive, etc.

(Light Source Unit 2)

Next, the light source unit 2 according to the first embodiment of thedisclosure will be described. FIG. 14 illustrates a schematicconfiguration example of the light source unit 2 using the phosphorsubstrate 1 and the attachment 42, 44, or 45. The light source unit 2includes the light conversion section 2A to which the phosphor substrate1 and the attachment 42, 44, or 45 described above are applied. Thelight source unit 2 includes the light conversion section 2A and a lightsource section 2B.

The light source section 2B is intended to irradiate the lightconversion section 2A with exciting light L1. The light source section2B corresponds to a specific example of a “light source” of thedisclosure. The light source section 2B has, for example, two lightsources 111, condensing mirrors 112,113, and 114, and a dichroic mirror115. The light sources 111 each output light (the exciting light L1)having a peak wavelength of light-emission intensity within a wavelengthrange suitable for exciting of the phosphor layer 10. Assume that thephosphor layer 10 includes a fluorescent substance that emits yellowfluorescence when excited by light (blue light) having a wavelengthwithin a wavelength range of 400 nm to 500 nm. In this case, the lightsources 111 each include, for example, a semiconductor laser or a lightemitting diode that outputs blue light having a peak wavelength oflight-emission intensity within the wavelength range of 400 nm to 500nm, as the exciting light L1.

The condensing mirrors 112 and 113 are each, for example, a concavereflecting mirror, and reflect the light (the exciting light L1)outputted from the two light sources 111 toward the condensing mirror114 and to condense the light. The condensing mirror 114 is, forexample, a convex reflecting mirror, and brings the reflected lightderived from the condensing mirrors 112 and 113 into parallel light toreflect this light toward the phosphor layer 10.

The dichroic mirror 115 reflects color light of a predeterminedwavelength region selectively, and allows light of other wavelengthregions to pass therethrough. The dichroic mirror 115 allows the light(the exciting light L1) outputted from the two light sources 111 to passtherethrough, and reflects light (fluorescence Lb) outputted from thephosphor layer 10. The dichroic mirror 115 is also allows light L3outputted from a light source 117 described later to pass therethrough.Here, a traveling direction of the fluorescence Lb after reflected bythe dichroic mirror 115 and a traveling direction of the light L3 areequal to each other. The dichroic mirror 115 therefore mixes thefluorescence Lb and the light L3 with each other, and outputs the mixedlight in a predetermined direction. The light L3 is light having a peakwavelength of light-emission intensity within a wavelength range commonto the exciting light L1. In a case where the exciting light L1 is bluelight having a peak wavelength of light-emission intensity within thewavelength range of 400 nm to 500 nm, the light L3 is also blue lighthaving a peak wavelength of light-emission intensity within thewavelength range of 400 nm to 500 nm.

The light source section 2B is intended to generate the light L3 thatmakes it possible to generate white light Lw by being mixed with thelight (the fluorescence Lb) outputted from the light conversion section2A. The light source section 2B further includes, for example, the onelight source 117, and a condensing lens 116. The light source 117outputs the light L3. The light source 117 includes a semiconductorlaser or a light emitting diode that outputs the light L3. Thecondensing lens 116 condenses the mixed light (the white light Lw)generated by the dichroic mirror 115 and outputs the mixed light towardother optical system.

The light conversion section 2A is intended to output the fluorescenceLb having a peak of light-emission intensity within a wavelength rangedifferent from the wavelength range of the exciting light L1, toward thelight source section 2B. The light conversion section 2A outputs thefluorescence Lb to the light source section 2B, by using the lightoutputted from the light source section 2B, as the exciting light L1.The light conversion section 2A has the phosphor substrate 1, a motor121 coupled to the phosphor substrate 1 through the attachment 42, 44,or 45, and a condensing lens 122 disposed at a position facing a topsurface of the phosphor substrate 1 with a predetermined gap formedtherebetween. The motor 121 corresponds to a specific example of a“motor” of the disclosure. The attachments 42, 44, and 45 each transmitrotation driving force of the motor 121 to the substrate 20. Thecondensing lens 122 is intended to condense the exciting light L1inputted from the light source section 2B to irradiate a predeterminedposition of the phosphor layer 10. The condensing lens 122 includes, forexample, a lens 122 a and a lens 122 b.

FIG. 15 and FIG. 16 illustrate an example of application of the excitinglight L1 to the phosphor substrate 1, in the light source unit 2. Thecondensing lens 124 is configured such that an outer edge of the topsurface of the phosphor layer 10 is irradiated with the exciting lightL1 after condensed by the condensing lens 124. Here, assume that whenthe phosphor layer 10 does not rotate, a portion to be irradiated withthe exciting light L1 is an optical irradiation point 10A, in thephosphor layer 10. When the phosphor layer 10 is to be irradiated withthe exciting light L1, the phosphor layer 10 rotates about the rotationaxis AX1 together with the substrate 20 and therefore, the outer edge ofthe top surface of the phosphor layer 10 is circularly irradiated withthe exciting light L1, while the phosphor layer 10 rotates. The opticalirradiation point 10A therefore moves along the outer edge of the topsurface of the phosphor layer 10, while the phosphor layer 10 rotates.It is to be noted that the optical irradiation region 10B in FIG. 16corresponds to a ring-shaped region through which the opticalirradiation point 10A passes, on the top surface of the phosphor layer10.

Incidentally, assume that an energy distribution of the exciting lightL1 is a Gaussian distribution. In this case, the exciting light L1 has abeam diameter corresponding to a diameter of a bundle of rays having astrength of 1/e² (=13.5%) of a central strength. Here, assume that theoptical irradiation point 10A has a diameter equal to the beam diameterof the exciting light L1. At this time, the optical irradiation region10B has a line width equal to the diameter of the optical irradiationpoint 10A and therefore, the line width of the optical irradiationregion 10B is equal to the beam diameter of the exciting light L1.

Here, 99.9% or more of total energy of the exciting light L1 is in abundle of rays having a diameter 1.52 times longer than the beamdiameter of the exciting light L1. It is therefore preferable that thecondensing lens 122 be disposed such that the top surface of thephosphor layer 10 is irradiated with the bundle of rays having thediameter 1.52 times longer than the beam diameter of the exciting lightL1 (the diameter of the optical irradiation point 10A). Assume that thebeam diameter of the exciting light L1 (the diameter of the opticalirradiation point 10A) is 3 mm from a viewpoint such as light conversionefficiency. At the time, it is preferable that the condensing lens 122be disposed such that the center of the optical irradiation point 10A islocated at a position 2.28 mm (=3 mm×1.52/2) or more away from an endedge of the top surface of the phosphor layer 10.

It is to be noted that the condensing lens 124 may be disposed such thatthe center of the optical irradiation point 10A is located at a positiononly 2.28 mm (=3 mm×1.52/2) from the end edge of the top surface of thephosphor layer 10. At this time, a stripe-shaped region between the endedge of the top surface of the phosphor layer 10 and a position 4.56 mm(=2.28 mm×2) away from the end edge of the top surface of the phosphorlayer 10 is irradiated with the bundle of rays having the diameter 1.52times longer than the beam diameter of the exciting light L1 (thediameter of the optical irradiation point 10A). In this case, therefore,of the phosphor layer 10, a portion away from the end edge of the topsurface of the phosphor layer 10 by more than 4.56 mm does notcontribute to generation of the exciting light Lb. For this reason, thephosphor layer 10 may be configured by only a portion contributing tothe generation of the exciting light Lb, or may have, for example, aring shape having the opening 10H, as illustrated in FIG. 17 and FIG.18. At this time, the phosphor layer 10 has a line width greater thanthe diameter 1.52 times longer than the beam diameter of the excitinglight L1 (the diameter of the optical irradiation point 10A). In a casewhere the beam diameter of the exciting light L1 (the diameter of theoptical irradiation point 10A) is 3 mm from the viewpoint such as thelight conversion efficiency, the line width of the phosphor layer 10 isgreater than 4.56 mm.

[Effects]

Next, effects of the phosphor substrate 1 and the light source unit 2 ofthe present embodiment will be described.

In general, for light emission of a phosphor layer, there is aphenomenon called luminance saturation or temperature quenching. This issuch a phenomenon that, in a case where an output of exciting light isincreased, a part of a conversion loss in a phosphor layer changes toheat that causes the phosphor layer to generate heat, and fluorescenceconversion efficiency thereby drops. In a state where the fluorescenceconversion efficiency is low, an efficient, bright light source unit isnot implementable. Hence, the phosphor layer is provided on a surface ofa substrate having high thermal conductivity.

Incidentally, a phosphor layer and a substrate provided with thephosphor layer are fixed to each other through a bonding layer, etc., ordirectly fixed to each other by ambient temperature bonding or opticalcontact. Hence, in a case where warping occurs in the substrate due tostress caused by thermal expansion of each of the phosphor layer and thesubstrate, and a focal position of exciting light is thereby displaced,fluorescence conversion efficiency may drop.

In the present embodiment, however, the phosphor layer 10 is disposed atthe center of the substrate 20. For this reason, even if warping occursin the substrate 20 due to the stress caused by the thermal expansion ofeach of the phosphor layer 10 and the substrate 20, it is possible tomake a displacement amount of the phosphor layer 10 small, as comparedwith a case where a phosphor layer is disposed on an outer edge of asubstrate or the entire substrate. As a result, it is possible to reducea displacement of a focal position due to the thermal expansion.

In addition, in the present embodiment, in a case where the substrate 20and the phosphor layer 10 are configured of materials in which thedifference in linear expansion coefficient between the substrate 20 andthe phosphor layer 10 is 1×10⁻⁶ cm/° C. or less, it is possible to makea displacement amount of the phosphor layer 10 small, as compared with acase where a substrate and a phosphor layer are configured of materialsin which a difference in linear expansion coefficient between thesubstrate and the phosphor layer 10 exceeds 1×10⁻⁶ cm/° C. As a result,it is possible to reduce the displacement of the focal position due tothe thermal expansion.

Further, in general, a phosphor layer is rotated by a motor attached toa substrate having high thermal conductivity. In a case where heatgenerated in the phosphor layer is transferred to the motor through thesubstrate, reliability of the motor may decrease due to a temperaturerise of the motor.

In the present embodiment, however, there is provided the attachment 42,44, or 45 that supports the portion, of the substrate 20, except for thecenter of the substrate 20. This makes it difficult for the heatgenerated in the phosphor layer 10 to travel to the motor 121 throughthe substrate 20, as compared with a case where an attachment supportsthe entire center, of the substrate 20, at which the phosphor layer 10is disposed. As a result, it is possible to suppress a decline inreliability of the motor 121 due to a temperature rise of the motor 121.

<2. Second Embodiment>

[Configuration]

Next, a projector 5 according to a third embodiment of the disclosurewill be described. The projector 5 corresponds to a specific example ofa “projection-type display” of the disclosure. FIG. 19 illustrates aschematic plane configuration example of the projector 5 according tothe third embodiment of the disclosure. The projector 5 includes theabove-described light source unit 2 or the above-described light sourceunit 4. The projector 5 further includes an image generation system 6and a projection optical system 7.

The image generation system 6 generates image light of a plurality ofcolors by modulating the light (the white light Lw) outputted from theabove-described light source unit 2 or the above-described light sourceunit 4 on the basis of an image signal, and combines the generated imagelight of plurality of colors to output the combined image light to theprojection optical system 7. The image generation system 6 has anillumination optical system 410, an image generation section 420, and animage combining section 430. The projection optical system 7 projectsthe image light (the combined image light) outputted from the imagegeneration system 6, onto a screen, etc. The image generation system 6corresponds to a specific example of an “optical modulation section” ofthe disclosure. The projection optical system 7 corresponds to aspecific example of a “projection section” of the disclosure.

The illumination optical system 410 separates the light (the white lightLw) outputted from the above-described light source unit 2 or theabove-described light source unit 4 into a plurality of pieces of colorlight. The illumination optical system 410 has, for example, anintegrator device 411, a polarization conversion device 412, acondensing lens 413, dichroic mirrors 414 and 415, and mirrors 416 to418. The integrator device 411 has, for example, a fly-eye lens 411 aand a fly-eye lens 411 b. The fly-eye lens 411 a has a plurality ofmicro-lenses arranged two-dimensionally. The fly-eye lens 411 b also hasa plurality of micro-lenses arranged two-dimensionally. The fly-eye lens411 a divides the light (the white light Lw) outputted from theabove-described light source unit 2 or the above-described light sourceunit 4 into a plurality of bundle of rays, and forms an image at each ofthe micro-lenses in the fly-eye lens 411 b. The fly-eye lens 411 bserves as a secondary light source, and allows a plurality of pieces ofparallel light of the same luminance as each other to enter thepolarization conversion device 412. The dichroic mirrors 414 and 415reflect color light of a predetermined wavelength region selectively,and allow light of other wavelength regions to pass therethrough. Thedichroic mirror 414 reflects, for example, red light selectively. Thedichroic mirror 415 reflects, for example, green light selectively.

The image generation section 420 modulates each of the pieces of colorlight separated by the illumination optical system 410, on the basis ofan image signal corresponding to each of colors inputted from outside,and generates image light of each of the colors. The image generationsection 420 has, for example, a light valve 421 for red light, a lightvalve 422 for green light, and a light valve 423 for blue light. Thelight valve 421 for red light modulates red light inputted from theillumination optical system 410, on the basis of an image signalcorresponding to red inputted from outside, and thereby generates redimage light. The light valve 422 for green light modulates green lightinputted from the illumination optical system 410, on the basis of animage signal corresponding to green inputted from outside, and therebygenerates green image light. The light valve 423 for blue lightmodulates blue light inputted from the illumination optical system 410,on the basis of an image signal corresponding to blue inputted fromoutside, and thereby generates image light of the blue.

The image combining section 430 combines the image light of each of thecolors generated in the image generation section 420, and therebygenerates color image light.

[Effects]

Next, effects of the projector 5 of the present embodiment will bedescribed.

In the present embodiment, the light source unit 2 of theabove-described embodiment or the light source unit 4 of theabove-described embodiment is used as a light source. This makes itpossible to reduce the displacement of the focal position due to thethermal expansion in the light source unit 2 of the above-describedembodiment or the light source unit 4 of the above-described embodimentand thus, it is possible to suppress luminance of the color image lightoutputted from the projector 5 from becoming lower than a desirablevalue.

As described above, the disclosure is described by referring to thethree embodiments, but the disclosure is not limited to each of theabove-described embodiments, and various modifications may be made. Itis to be noted that the effects described herein are mere examples.Effects of the disclosure are not limited to the effects describedherein. The disclosure may have effects other than the effects describedherein.

For example, in the above-described embodiments, the example in whichthe disclosure is applied to the light source unit of the projector 5 isdescribed, but of course, it is also possible to apply the disclosureto, for example, an illumination unit. Examples of the illumination unitinclude a headlight of a vehicle, etc.

In addition, for example, the technology may adopt the followingconfigurations.

-   (1) A light source unit including:    -   a substrate configured to be rotatable;    -   a phosphor layer disposed at a center of the substrate;    -   a light source that irradiates the phosphor layer with exciting        light; and    -   a support section that supports a portion, of the substrate,        except for the center of the substrate.-   (2) The light source unit according to (1), in which the support    section supports a portion, of the substrate, not facing the    phosphor layer.-   (3) The light source unit according to (1) or (2), in which the    support section supports only the portion, of the substrate, not    facing the phosphor layer.-   (4) The light source unit according to (3), in which    -   the support section has a first concave section having a recess        formed at least at a portion facing the phosphor layer, and    -   the first concave section forms a clearance between a portion,        of the substrate, facing the phosphor layer and the support        section.-   (5) The light source unit according to (3), in which    -   the support section has a plurality of convex sections at a        portion not facing the phosphor layer, and    -   the plurality of convex sections form a clearance between a        portion, of the substrate, facing the phosphor layer and the        support section.-   (6) The light source unit according to (1) or (2), in which the    support section supports the portion, of the substrate, not facing    the phosphor layer and a part of a portion, of the substrate, facing    the phosphor layer.-   (7) The light source unit according to (6), in which    -   the support section has a plurality of second concave sections        at a portion facing the phosphor layer, and    -   the second concave sections each form a clearance between the        support section and the substrate.-   (8) The light source unit according to (5), in which the support    section has a fixing section that fixes a shaft of a motor, at an    undersurface of the first concave section.-   (9) The light source unit according to (8), in which the support    section has a ring-shaped second concave section, around the fixing    section, of the undersurface of the first concave section.-   (10) The light source unit according to any one of (1) to (9), in    which    -   the substrate and the phosphor layer have a disk shape, and    -   the phosphor layer is disposed concentrically with the        substrate.-   (11) The light source unit according to any one of (1) to (9), in    which    -   the substrate has a disk shape, and    -   the phosphor layer has a ring shape, and is disposed        concentrically with the substrate.-   (12) The light source unit according any one of (1) to (11), in    which    -   the light source unit has a motor coupled to the support        section, and    -   the support section transmits rotation driving force of the        motor to the substrate.-   (13) A projection-type display including:    -   a substrate configured to be rotatable;    -   a phosphor layer disposed at a center of the substrate;    -   a light source that irradiates the phosphor layer with exciting        light;    -   a support section that supports a portion, of the substrate,        except for the center of the substrate;    -   an optical modulation section that generates image light by        modulating the exciting light outputted from the light source,        on a basis of an image signal; and    -   a projection section that projects the image light generated by        the optical modulation section.

This application is based upon and claims the benefit of priority of theJapanese Patent Application No. 2015-099920 filed with the Japan PatentOffice on May 15, 2015, the entire contents of which are incorporatedherein by reference.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations, and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

The invention claimed is:
 1. A light source unit, comprising: asubstrate that is rotatable; a phosphor layer at a center of thesubstrate; a light source configured to irradiate the phosphor layerwith exciting light; and a rotatable support section configured tosupport a first portion of the substrate, wherein the first portion isother than the center of the substrate.
 2. The light source unitaccording to claim 1, wherein the first portion of the substrate isother than a second portion of the substrate that faces the phosphorlayer.
 3. The light source unit according to claim 2, wherein therotatable support section is further configured to support the firstportion of the substrate.
 4. The light source unit according to claim 3,wherein the rotatable support section has a first concave section havinga recess formed at the second portion of the substrate, and the firstconcave section forms a first clearance between the second portion ofthe substrate and the rotatable support section.
 5. The light sourceunit according to claim 3, wherein the rotatable support section has aplurality of convex sections at the first portion of the substrate, andthe plurality of convex sections form a clearance between the firstportion of the substrate and the rotatable support section.
 6. The lightsource unit according to claim 2, wherein the rotatable support sectionis further configured to support the first portion of the substrate anda part of the second portion of the substrate.
 7. The light source unitaccording to claim 4, wherein the rotatable support section has aplurality of second concave sections at the second portion of thesubstrate, and each second concave section of the plurality of secondconcave sections forms a second clearance between the rotatable supportsection and the substrate.
 8. The light source unit according to claim4, wherein the rotatable support section has a fixing section that fixesa shaft of a motor, at an undersurface of the first concave section. 9.The light source unit according to claim 8, wherein the rotatablesupport section has a second concave section, around the fixing section,of the undersurface of the first concave section, and a shape of thesecond concave section is ring-shaped.
 10. The light source unitaccording to claim 2, wherein the substrate and the phosphor layer havea disk shape, and the phosphor layer is concentric with the substrate.11. The light source unit according to claim 2, wherein the substratehas a disk shape, the phosphor layer has a ring shape, and the phosphorlayer is concentric with the substrate.
 12. The light source unitaccording to claim 2, further comprising a motor coupled to therotatable support section, wherein the rotatable support section isfurther configured to transmit rotation driving force of the motor tothe substrate.
 13. A projection-type display, comprising: a substratethat is rotatable; a phosphor layer at a center of the substrate; alight source configured to irradiate the phosphor layer with excitinglight; a rotatable support section configured to support a portion ofthe substrate, wherein the portion is other than the center of thesubstrate; an optical modulation section configured to generate imagelight by modulation of the exciting light, wherein the modulation isbased on an image signal; and a projection section is configured toproject the image light.
 14. A light source unit, comprising: asubstrate that is rotatable; a phosphor layer at a center of thesubstrate; a light source configured to irradiate the phosphor layerwith exciting light; a support section configured to support a portion,of the substrate, except for the center of the substrate, wherein thesupport section is configured to support the portion, of the substrate,not facing the phosphor layer; and a motor coupled to the supportsection, wherein the support section is further configured to transmitrotation driving force of the motor to the substrate.
 15. A light sourceunit, comprising: a substrate that is rotatable; a phosphor layer at acenter of the substrate; a light source configured to irradiate thephosphor layer with exciting light; and a support section configured tosupport a portion, of the substrate, except for the center of thesubstrate, wherein the support section is configured to support theportion, of the substrate, not facing the phosphor layer and a part of aportion, of the substrate, facing the phosphor layer.
 16. A light sourceunit, comprising: a substrate that is rotatable; a phosphor layer at acenter of the substrate; a light source configured to irradiate thephosphor layer with exciting light; and a support section configured tosupport a portion, of the substrate, except for the center of thesubstrate, wherein the support section is configured to support theportion, of the substrate, not facing the phosphor layer, the substratehas a disk shape, the phosphor layer has a ring shape, and the phosphorlayer is disposed concentrically with the substrate.